Semiconductor substrate, method of manufacturing the same, semiconductor device, and method of manufacturing the same

ABSTRACT

A semiconductor substrate is disclosed which comprises a first single crystal silicon layer, an insulator formed to partially cover one main surface of the first single crystal silicon layer, a second single crystal silicon layer formed to cover a region of the first single crystal silicon layer which is not covered with the insulator, and to cover an edge portion of the insulator adjacent to the region, and a non-single crystal silicon layer formed on the insulator, the interface between the non-single crystal silicon layer and the second single crystal silicon layer being positioned on the insulator.

This application is a continuation of Ser. No. 10/439,896, filed May 16,2003 now U.S. Pat. No. 7,122,864, the entire contents of which areincorporated herein by reference.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is based upon and claims the benefit of priority fromthe prior Japanese Patent Application No. 2003-072218, filed Mar. 17,2003, the entire contents of which are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a semiconductor substrate having apartially formed SOI region. In particular, the present inventionrelates to a semiconductor substrate having a single crystal siliconlayer formed by epitaxial growth. In addition, the present inventionrelates to a semiconductor device including the semiconductor substrate,and methods of manufacturing these semiconductor substrate and device.

2. Description of the Related Art

Recently, demands for semiconductor devices embedding high performancelogic circuit and DRAM are greatly growing. In order to meet thedemands, the following technique is much required. According to thetechnique, a DRAM is embedded in a high performance logic circuit usinga semiconductor substrate (SOI substrate) having an SOI (Silicon OnInsulator) structure. In particular, a SOI-MOSFET having MOSFET formedon the SOI substrate is hopeful as the high performance logic circuit.

However, even if gate voltage is (OFF state) due to a so-calledsubstrate floating effect, parasitic MOSFET and bipolar currents flow,as the leakage current between the source and drain depend on thepotential difference between source and drain. Such a phenomenon is afactor of causing the reduction of deterioration in memory celltransistors of DRAMs, that is, portions requiring strict specificationsagainst leakage current. In addition, the threshold value of pairtransistors included in a DRAM sense amplifier circuit shifts due to thesubstrate floating effect; and due to this, the sense margin lowers. Dueto this, it is difficult to form a DRAM having the same MOSFET structureas a high performance logic circuit on a general SOI substrate.

The use of a so-called partial SOI substrate having a partial SOIstructure has been tried. In a partial SOI structure, a silicon layer iscomposed of two regions, that is, an SOI region and a non-SOI region.For example, the transistor is formed in the non-SOI region (bulkregion), and thereby, it is possible to prevent the substrate floatingeffect. As described above, the partial SOI substrate is effective incircuits requiring both an SOI region and bulk region, such as DRAMembedded LOGIC and embedded DRAM (eDRAM).

The following method of manufacturing a partial SOI substrate isemployed. According to the method, a SOI layer on the SOI substrate anda BOX (Buried Oxide) layer are selectively removed by etching to form aregion, and this formed region is again covered with silicon. Inaddition, the following method is employed. According to the method,oxygen is partially implanted in the silicon substrate, and an isolationoxide film is formed only in the implanted region. However, according tothe methods described above, if the bulk region adjacent to the SOIregion is contaminated with heavy metals, the gettering ability of theSOI region is not sufficient. For this reason, it is difficult to stablyobtain a stable yield. A so-called bonding method is employed other thanthese methods described above. According to the bonding method, an oxidefilm is formed on part of the silicon substrate, and silicon isdeposited on the oxide film. Thereafter, the formed silicon substrateand another silicon substrate are bonded together so that a partial SOIstructure can be made. The bonding method will be briefly describedbelow with reference to FIG. 7A to FIG. 7F, FIG. 8A and FIG. 8B.

As illustrated in FIG. 7A, a multi-layer comprising a non-single crystalsilicon film 102, single crystal silicon film 103 and silicon oxide film(SiO₂ film) 104 is formed on one main surface of a silicon substrate101. As shown in FIG. 7B, the SiO₂ film 104 is partially removed so thatthe surface of the single crystal silicon film 103 can be partiallyexposed. As seen from FIG. 7C, a silicon film 105 is deposited on thesingle crystal silicon film 103 and the SiO₂ film 104 by epitaxialgrowth. In this case, the silicon film 105 is formed while being dividedinto two kinds of layer, due to the difference of the material qualityof the front end (seed layer). Most of the silicon film 105 a on thesingle crystal silicon film 103 is formed as a single crystal siliconfilm (layer) 105 a. On the contrary, a silicon film 105 b on the SiO₂film 104 is formed as a polycrystalline silicon film (layer) 105 b. Thesingle crystal silicon film 105 a is deposited on the single crystalsilicon film 103 while being integrated with the single crystal siliconfilm 103.

As shown in FIG. 7D, the surface of the single crystal silicon film 105a and the polycrystalline silicon film 105 b is planarized. Thereafter,another silicon substrate 106 used as a support substrate (base wafer)is bonded onto the surface of the films 105 a and 105 b. The siliconsubstrate 106 is formed of single crystal silicon, and integrated withthe single crystal silicon film 105 a. As illustrated in FIG. 7E, thesilicon substrate 101 is cut off in the non-single crystal silicon film102. Thereafter, an active layer side silicon film (single crystalsilicon film 103) formed with semiconductor devices (not shown) is madethin. As seen from FIG. 7F, the non-single crystal silicon film 102 ispolished and removed. Thereafter, predetermined surface processing, suchas planarization, is subjected to the surface of the single crystalsilicon film 103. The process described above is carried out, andthereby, a partial SOI substrate 107 having a partial SOI structure ismanufactured.

In the partial SOI substrate 107, the polycrystalline silicon film(non-single crystal-silicon film) 105 b adjacent to the single crystalsilicon film 105 a functions as a gettering site. Thus, a high yield canbe stably obtained. However, the polycrystalline silicon film 105 b hasa growth rate higher than the single crystal silicon film 105 a. Forthis reason, the interface between the single crystal silicon film 105 aand the polycrystalline silicon film 105 b is inclined to the singlecrystal silicon film 105 a side, as shown in FIG. 7C. As a result, asseen from FIG. 8A, in the non-SOI region (bulk region), an elementformable region having a sufficient film thickness (depth) for formingburied semiconductor elements decreases. In addition, the decreasedamount increases while the required thickness becomes gradually thick,as seen from FIG. 8B. For example, the element formable region is formedthicker in order to form devices such as memory trench cells extendingin the depth direction. In this case, there is a high possibility thatthe element crosses the interface (epi/sub surface) between the singlecrystal silicon film 105 a and the polycrystalline silicon film 105 b.

As described above, it is difficult to form the semiconductor elementssuch as DRAM on the general SOI substrate having the possibility ofcausing substrate floating effect. In addition, the method of formingthe partial SOI structure having the following SOI region usingepitaxial growth is not still established. The SOI region has getteringability sufficient to adjacent bulk region, and has no possibility ofreducing the bulk region (element formable region).

BRIEF SUMMARY OF THE INVENTION

According to an aspect of the invention, there is provided asemiconductor substrate comprising: a first single crystal siliconlayer; an insulator formed to partially cover one main surface of thefirst single crystal silicon layer; a second single crystal siliconlayer formed to cover a region of the first single crystal silicon layerwhich is not covered with the insulator, and to cover an edge portion ofthe insulator adjacent to the region; and a non-single crystal siliconlayer formed on the insulator, the interface between the non-singlecrystal silicon layer and the second single crystal silicon layer beingpositioned on the insulator.

According to another aspect of the invention, there is provided a methodof manufacturing a semiconductor substrate comprising: forming aninsulator to partially cover one main surface of a first single crystalsilicon layer; epitaxially growing a second single crystal silicon layeron an exposed surface of the first single crystal silicon layer which isnot covered with the insulator, to cover an edge portion of theinsulator adjacent to the exposed surface; and forming a non-singlecrystal silicon layer on an exposed surface of the insulator with an endof an interface between the insulator and the non-single crystal siliconlayer kept away from an end of the insulator by a predetermineddistance, while further epitaxially growing the second single crystalsilicon layer.

According to another aspect of the invention, there is provided a methodof manufacturing a semiconductor substrate comprising: forming aninsulator to partially cover one main surface of a first single crystalsilicon layer; forming an amorphous silicon layer to cover a surface ofthe insulator and an exposed surface of the first single crystal siliconlayer which is not covered with the insulator; and heating the amorphoussilicon layer. until the amorphous silicon layer on the exposed surfaceof the first single crystal silicon layer which is not covered with theinsulator, is modified into a second single crystal silicon layer byselectively and solid-phase epitaxially growing, using the first singlecrystal silicon layer as a seed layer.

According to further aspect of the invention, there is provided asemiconductor device comprising: a semiconductor substrate; thesemiconductor substrate including: a first single crystal silicon layer;an insulator formed to partially cover one main surface of the firstsingle crystal silicon layer; a second single crystal silicon layerformed to cover a region of the first single crystal silicon layer whichis not covered with the insulator, and to cover an edge portion of theinsulator adjacent to the region; and a non-single crystal silicon layerformed on the insulator, the interface between the non-single crystalsilicon layer and the second single crystal silicon layer beingpositioned on the insulator; a first semiconductor element formed on ansurface of the first single crystal silicon layer or in a range from thesurface to a predetermined inside position of the first single crystalsilicon layer, at a position off the insulator of the semiconductorsubstrate; and a second semi-conductor element formed in a range fromthe surface of the first single crystal silicon layer to at least insideof the second single crystal silicon layer, at a position off theinsulator of the semiconductor substrate.

According to further aspect of the invention, there is provided asemiconductor device comprising: a semiconductor substrate; thesemiconductor substrate manufactured by; forming an insulator topartially cover one main surface of a first single crystal siliconlayer; epitaxially growing a second single crystal silicon layer on anexposed surface of the first single crystal silicon layer which is notcovered with the insulator, to cover an edge portion of the insulatoradjacent to the exposed surface; and forming a non-single crystalsilicon layer on an exposed surface of the insulator while furtherepitaxially growing the second single crystal silicon layer; a firstsemiconductor element formed on an surface of the first single crystalsilicon layer or in a range from the surface to a predetermined insideposition of the first single crystal silicon layer, at a position offthe insulator of the semiconductor substrate; and a second semiconductorelement formed in a range from the surface of the first single crystalsilicon layer to at least inside of the second single crystal siliconlayer, at a position off the insulator of the semi-conductor substrate.

According to further aspect of the invention, there is provided asemiconductor device comprising: a semiconductor substrate; thesemiconductor substrate manufactured by; forming an insulator topartially cover one main surface of a first single crystal siliconlayer; forming an amorphous silicon layer to cover a surface of theinsulator and an exposed surface of the first single crystal siliconlayer which is not covered with the insulator; and heating the amorphoussilicon layer until the amorphous silicon layer on the exposed surfaceof the first single crystal silicon layer which is not covered with theinsulator, is modified into a second single crystal silicon layer byselectively and solid-phase epitaxially growing, using the first singlecrystal silicon layer as a seed layer; a first semiconductor elementformed on an surface of the first single crystal silicon layer or in arange from the surface to a predetermined inside position of the firstsingle crystal silicon layer, at a position off the insulator of thesemiconductor substrate; and a second semiconductor element formed in arange from the surface of the first single crystal silicon layer to atleast inside of the second single crystal silicon layer, at a positionoff the insulator of the semi-conductor substrate.

According to yet another aspect of the invention, there is provided amethod of manufacturing a semiconductor device comprising: manufacturinga semiconductor substrate; the semiconductor substrate including; afirst single crystal silicon layer; an insulator formed to partiallycover one main surface of the first single crystal silicon layer; asecond single crystal silicon layer formed to cover a region of thefirst single crystal silicon layer which is not covered with theinsulator, and to cover an edge portion of the insulator adjacent to theregion; and a non-single crystal silicon layer formed on the insulator,the interface between the non-single crystal silicon layer and thesecond single crystal silicon layer being positioned on the insulator;forming a first semiconductor element on an surface of the first singlecrystal silicon layer or in a range from the surface to a predeterminedinside position of the first single crystal silicon layer, at a positionoff the insulator of the semiconductor substrate; and forming a secondsemiconductor element in a range from a surface of the first singlecrystal silicon layer to at least inside of the second single crystalsilicon layer, at a position off the insulator of the semiconductorsubstrate.

According to yet another aspect of the invention, there is provided amethod of manufacturing a semiconductor device comprising: manufacturinga semiconductor substrate; the semiconductor substrate including;forming an insulator to partially cover one main surface of a firstsingle crystal silicon layer; epitaxially growing a second singlecrystal silicon layer on an exposed surface of the first single crystalsilicon layer which is not covered with the insulator, to cover an edgeportion of the insulator adjacent to the exposed surface; and forming anon-single crystal silicon layer on an exposed surface of the insulatorwhile further epitaxially growing the second single crystal siliconlayer; forming a first semiconductor element on an surface of the firstsingle crystal silicon layer or in a range from the surface to apredetermined inside position of the first single crystal silicon layer,at a position off the insulator of the semiconductor substrate; andforming a second semiconductor element in a range from a surface of thefirst single crystal silicon layer to at least inside of the secondsingle crystal silicon layer, at a position off the insulator of thesemiconductor substrate.

According to yet another aspect of the invention, there is provided amethod of manufacturing a semiconductor device comprising: manufacturinga semiconductor substrate; the semiconductor substrate including;forming an insulator to partially cover one main surface of a firstsingle crystal silicon layer; forming an amorphous silicon layer tocover a surface of the insulator and an exposed surface of the firstsingle crystal silicon layer which is not covered with the insulator;and heating the amorphous silicon layer until the amorphous siliconlayer on the exposed surface of the first single crystal silicon layerwhich is not covered with the insulator, is modified into a secondsingle crystal silicon layer by selectively and solid-phase epitaxiallygrowing, using the first single crystal silicon layer as a seed layer;forming a first semiconductor element on an surface of the first singlecrystal silicon layer or in a range from the surface to a predeterminedinside position of the first single crystal silicon layer, at a positionoff the insulator of the semiconductor substrate; and forming a secondsemiconductor element in a range from a surface of the first singlecrystal silicon layer to at least inside of the second single crystalsilicon layer, at a position off the insulator of the semiconductorsubstrate.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING

FIG. 1A to FIG. 1E are process sectional views showing a method ofmanufacturing a semiconductor substrate according to a first embodiment;

FIG. 2A to FIG. 2C are process sectional views. showing a method ofmanufacturing a semiconductor substrate according to a first embodiment;

FIG. 3 is a cross-sectional view showing a semiconductor deviceaccording to a first embodiment;

FIG. 4A to FIG. 4E are process sectional views showing a method ofmanufacturing a semiconductor substrate according to a secondembodiment;

FIG. 5A to FIG. 5D are process sectional views showing a method ofmanufacturing a semiconductor substrate according to a secondembodiment;

FIG. 6 is a cross-sectional view showing a semiconductor deviceaccording to a second embodiment;

FIG. 7A to FIG. 7F are process sectional views showing a method ofmanufacturing a semiconductor substrate according to a conventionaltechnique; and

FIG. 8A and FIG. 8B are cross-sectional views showing a method ofmanufacturing the semiconductor substrate according to the conventionaltechnique.

DETAILED DESCRIPTION OF THE INVENTION

Embodiments of the present invention will be described below withreference to the accompanying drawings.

FIRST EMBODIMENT

The first embodiment of the present invention will be described withreference to FIG. 1A to FIG. 1E, FIG. 2A to FIG. 2C, and FIG. 3. FIG. 1Ato FIG. 1E and FIG. 2A to FIG. 2C are process sectional views showing amethod of manufacturing a semiconductor substrate according to the firstembodiment. FIG. 3 is a cross-sectional view showing a semiconductordevice according to the first embodiment.

The first embodiment relates to a semiconductor substrate and the methodof manufacturing the same. In particular, the first embodiment relatesto improvement in the method of manufacturing a partial SOI substrateusing a so-called bonding process and epitaxial growth. Morespecifically, a partial SOI substrate having the following partial SOIstructure is manufactured by a bonding process and two-stage epitaxialgrowth. According to the partial SOI structure, a non-single crystalsilicon layer in a SOI region does not intrude into a non-SOI regionadjacent to the SOI region.

As illustrated in FIG. 1A, a porous silicon layer 2 is formed on thesurface of a first silicon substrate 1 comprising single crystal siliconby anode formation process. The first silicon substrate 1 formed withthe porous silicon layer 2 is annealed under hydrogen atmosphere so thatthe surface layer of the porous silicon layer 2 can besingle-crystallized. By doing so, a first single crystal silicon layer 3is formed on the first silicon substrate 1. The first single crystalsilicon layer 3 is formed using the first silicon substrate 1 as a seedlayer by epitaxial growth. A thermal oxidation film 4 is formed on onemain surface of the first single crystal silicon layer (first epitaxialsilicon layer) 3 until it has a film thickness of about 0.2 μm. Morespecifically, the thermal oxidation film 4 is, a silicon oxide film(SiO₂ film). The SiO₂ film 4 calls buried insulator or buried oxide film(BOX layer: Buried Oxide layer).

As shown in FIG. 1B, of the SiO₂ film 4 formed on the surface of thefirst single crystal silicon layer 3, the SiO₂ film 4 equivalent to anon-SOI region described later is partially removed by normal patterningand etching. By doing so, the surface of a portion of the first singlecrystal silicon layer 3 included in the non-SOI region is temporarilyexposed. The region where the SiO₂ film 4 remains becomes a SOI regiondescribed later. In the remained SiO₂ film 4, the surface of the firstsingle crystal silicon layer 3 is subjected to predetermined masking(patterning). Therefore, the remained SiO₂ film 4 functions as a mask(oxide film mask) in the process of forming a second single crystalsilicon layer 5 described next.

As seen from FIG. 1C, the second single crystal silicon layer 5 isformed to cover the exposed surface of the first single crystal siliconlayer 3 except the SiO₂ film 4. The first silicon substrate 1 having thepartially removed SiO₂ film 4 is subjected to hydrogen cleaning at thetemperature of about 1000° C. By doing so, native oxide (not shown)formed on the exposed surface of the first single crystal silicon layer3 is removed. The first silicon substrate 1 removing the native oxide ishoused into a chamber (not shown). The internal pressure of the chamberis set to about 10 Torr while the first silicon substrate 1 is heateduntil the substrate temperature becomes 1000° C. Thereafter, materialgas containing dichloro-silane (DCS) and hydrochloric acid (HCl) issupplied to the exposed surface of the first single crystal siliconlayer 3 and the surface of the SiO₂ film 4. In this case, the DSC gasflow rate is set to about 0.25 slm. The HCl gas flow rate is set to 0.1slm.

When treatment (deposition) is carried out under the conditionsdescribed above, at the beginning of the treatment, single crystalsilicon is selectively deposited without depositing the single crystalsilicon on the surface of the oxide mask 4. In this case, the singlecrystal silicon is deposited only on the region of the first singlecrystal silicon layer 3 that is not covered with the oxide mask 4. Thatis, at the beginning of the treatment, the second single crystal siliconlayer 5 is epitaxially grown on only exposed surface of the first singlecrystal silicon layer 3. In this case, the second single crystal siliconlayer (second epitaxial silicon layer) 5 uses the first single crystalsilicon layer 3 as a seed layer. Further, the second single crystalsilicon layer 5 epitaxially grows while being integrated with the firstsingle crystal silicon layer 3. As described above, the material gascontaining chlorine (Cl) is used. By doing so, the second single crystalsilicon layer 5 can be selectively and epitaxially grown in accordancewith the material quality of the front end.

When the treatment is continued, the second single crystal silicon layer5 grows to the same height (thickness) as the oxide mask 4. Withextending a deposition time more, and thereby, the second single crystalsilicon layer 5 grows to ride on the surface of the edge portion of theoxide mask 4, as seen from FIG. 1D. Namely, the second single crystalsilicon layer 5 is formed on the exposed surface of the first singlecrystal silicon layer 3 except the oxide mask 4 to cover the edgeportion of the oxide mask 4 adjacent to the exposed surface. In theembodiment, the second single crystal silicon layer 5 is formed on theexposed surface of the first single crystal silicon layer 3 and thesurface of the edge portion of the oxide mask 4. In this case, thesecond single crystal silicon layer 5 is formed until the film thicknesson the first single crystal silicon layer 3 becomes about 0.4 μm. InFIG. 1D, the width W of the second single crystal silicon layer 5 ridingon the oxide mask 4 is about 0.18 μm.

As shown in FIG. 1E, a non-single crystal silicon layer 6 is formed onthe exposed surface of the oxide mask 4 covered with no second singlecrystal silicon layer 5, while epitaxially growing the second singlecrystal silicon layer 5. This process will be described below in detail.

The substrate temperature (deposition temperature) of the first siliconsubstrate 1 formed with the second single crystal silicon layer 5 isreduced from about 1000° C. to 700° C. Simultaneously, the material gassupplied into the chamber is changed from material gas containing Cl tomaterial gas containing no Cl. More specifically, SiH₄,gas is suppliedinto the chamber. When deposition is carried out under the conditionsdescribed above, the second single crystal silicon layer 5 continues toepitaxially grow, as illustrated in FIG. 1E. In this case, the secondsingle crystal silicon layer 5 grows entirely above the first singlecrystal silicon layer 3 regardless of the presence of the oxide mask 4.Simultaneously, a non-single crystal silicon layer 6 is deposited on theexposed surface of the oxide mask 4 except the second single crystalsilicon layer 5. The non-single crystal silicon layer 6 grows using theoxide mask 4 as the front-end layer, and thereby, is formed as apolycrystalline silicon layer. As described above, the material gascontaining no chlorine (Cl) is used. By doing so, the second singlecrystal silicon layer 5 and the polycrystalline silicon layer 6 canbe-concurrently formed in accordance with the material quality of thefront-end layer.

In general, many steps exist in the growth surface of thepolycrystalline silicon layer 6 as compared with that of the singlecrystal silicon layer 5, and adsorption probability of silicon atoms ishigh. Thus, the polycrystalline silicon layer has a higher growth speedthan the single crystal silicon layer under the same depositioncondition. For example, the single crystal silicon layer and thepolycrystalline silicon layer are formed from the same height under thesame deposition condition. In this case, as the deposition processadvances, the polycrystalline silicon layer grows so as to cover thesingle crystal silicon layer, although not illustrated. Namely, thesingle crystal and polycrystalline silicon layers concurrently grow sothat the interface between these silicon layers can be inclined to thesingle crystal silicon layer side.

As a result, according to the conventional method of manufacturing thepartial SOI substrate (partial SOI structure), the polycrystallinesilicon layer in the SOI region intrudes into the non-SOI region. Forthis reason, the element formable region in the non-SOI region (bulkregion) decreases. In particular, the element formable region havingsufficient film thickness (depth) for forming buried semiconductorelements, such as memory trench cell, extending in the depth direction,decreases. The decrease amount increases the thicker the required film.If the buried semiconductor element is formed in the element formableregion into which the polycrystalline silicon layer intrudes, there ishigh possibility as described below. That is, the semiconductor elementcrosses the interface between the single crystal silicon layer and thepolycrystalline silicon layer. If the semi-conductor element crosses theinterface between the silicon layers described above, the semiconductorelement cannot function normally. In addition, a semiconductor deviceprovided in a state that the semiconductor element crosses the interfacebetween the silicon layers is hard to normally function. The yield ofthe semiconductor device is reduced.

On the contrary, in the embodiment, the second single crystal siliconlayer 5 is previously formed as described before. In this case, thesecond single crystal silicon layer 5 is formed to cover the surface ofthe first single crystal silicon layer and the edge portion of the oxidemask 4 adjacent to there. By doing so, the deposition of the secondsingle crystal silicon layer 5 and the polycrystalline silicon layer 6starts. In this case, portions of the second single crystal siliconlayer 5, which are not formed on the oxide mask 4, mainly growepitaxially. Simultaneously, the polycrystalline silicon layer 6 isdeposited on the exposed surface of the oxide mask 4 and the surface ofthe second single crystal silicon layer 5 on the edge portion of theoxide mask 4. As described before, the polycrystalline silicon layer 6has a higher growth speed than the second single crystal silicon layer5. Nevertheless, when the deposition process is continued, the secondsingle crystal silicon layer 5 on the oxide mask 4 epitaxially grows tocover the polycrystalline silicon layer 6. Under the foregoingdeposition condition, the growth speed of the second single crystalsilicon layer 5 is about 0.25 μm/min. On the contrary, the growth speedof the polycrystalline silicon layer 6 is about 0.25 μm/min.

Thereafter, when the deposition process is continued, the single crystaland polycrystalline silicon layers 5 and 6 concurrently grow so that theinterface between these silicon layers 5 and 6 can be inclined to thesingle crystal silicon layer side. In the embodiment, the depositionprocess is continued for two minutes until the surfaces of the singlecrystal and polycrystalline silicon layers 5 and 6 reach approximatelythe same height. By doing so, the first silicon substrate 1 can beformed with the second single crystal silicon-layer 5 and thepolycrystalline silicon layer 6, which have almost no surface step.

Then, the surfaces of the second single crystal silicon layer 5 and thepolycrystalline silicon layers 6 reach approximately the same height. Atthis time, the interface between the silicon layers 5 and 6, that is, aninclination angle θ of the interface shown in FIG. 1E is about 30°.Namely, the interface between the silicon layers 5 and 6 is inclined atan angle of about 30° toward the oxide mask 4 from the normal directionof the oxide mask 4 (first silicon substrate 1). Of course, theinterface between the second single crystal and polycrystalline siliconlayers 5 and 6 exists on the oxide mask 4.

As depicted in FIG. 2A, a third single crystal silicon layer 7 is bondedto the surfaces of the second single crystal silicon layer 5 and thepolycrystalline silicon layers 6. More specifically, second siliconsubstrate 7 comprising single crystal silicon is bonded to the surfaceof the silicon layer 6. The second silicon substrate 7 is called asupport substrate, or handling wafer. The third single crystal siliconlayer 7 bonded to the surfaces of the second single crystal siliconlayer 5 and the polycrystalline silicon layers 6 is integrated with thesecond single crystal silicon layer 5. As illustrated in FIG. 2B, thefirst to third single crystal silicon layers 3, 5 and 7 are integratedinto one single silicon layer 8.

If the height of the surface of the second single crystal silicon layer5 has no coincidence with that of the polycrystalline silicon layers 6,it is difficult to accurately bond the second silicon substrate 7 on thesurfaces of these silicon layers. In this case, the surfaces of thesecond single crystal silicon layer 5 and the polycrystalline siliconlayers 6 are planarized before the third single crystal silicon layer 7is bonded to their surfaces. For example, the surfaces of the secondsingle crystal silicon layer 5 and the polycrystalline silicon layers 6are subjected to CMP so that they can be adjusted to the same height.

As seen from FIG. 2B and FIG. 2C, the active silicon layer comprisingthe first silicon substrate, porous silicon layer 2 and first singlecrystal layer 3 is made thin. According to the embodiment, in order tomake thin the active silicon layer, a so-called ELTRAN (EpitaxialTransfer) process is used because of readily controlling the thicknessof the silicon layer. More specifically, as illustrated in FIG. 2B, theporous layer 2 is cut using a water jet. As shown in FIG. 2C, the porouslayer 2 remaining on the surface (backside) of the first single crystalsilicon layer 1 is removed by wet etching. By doing so, the activesilicon layer is made. thin in a state that only the first singlecrystal silicon layer 3 is left on the active layer side. In addition,the surface of the remaining first single crystal silicon layer 3 issubjected to heat treatment under hydrogen atmosphere. By doing so, thesurface of the remaining first single crystal silicon layer 3, that is,the surface of the active silicon layer is planarized, which terminatesthe manufacturing process of this embodiment.

The processes described above are carried out to obtain a semiconductorsubstrate (partial SOI substrate) 11 having the desired partial SOIstructure. The partial SOI substrate 11 has the single crystal siliconlayer 8 comprising first to third single crystal silicon layers 3, 5 and7, SiO₂ film (insulator) 4 and the partial SOI structure having tworegions, as seen from FIG. 2C. The partial SOI structure includes a SOIregion 10 comprising the polycrystalline silicon layer (non-singlecrystal silicon layer) 6 and a non-SOI region (bulk region) 9 comprisingonly single crystal silicon layer 8. The SOI region 10 and the non-SOIregion 9 are adjacent to each other.

More specifically, in the partial SOI substrate 11, the SiO₂ film 4 ispartially formed on the active surface layer of the single crystalsilicon layer 8 along the surface of the single crystal silicon layer 8.The polycrystalline silicon layer 6 is formed contacting with the mainsurface of the SiO₂ film 4 opposite to the active surface layer of thesingle crystal silicon layer 8. Further, the silicon layer 6 is formedonly on the main surface of the SiO₂ film 4 so the interface with thesecond single crystal silicon layer 5 can be positioned on there.Namely, in the partial SOI substrate 11, the polycrystalline-siliconlayer 6 capable of performing gettering ability to the single crystalsilicon layer 8 is formed in only SOI region 10. Thus, the silicon layer6 does not intrude into the non-SOI region 9. Therefore, the non-SOIregion 9 can be entirely used as a good element formable region.

A semiconductor device of the first embodiment and the method ofmanufacturing the same will be described with reference to FIG. 3. Inthe semiconductor device of the embodiment and the method ofmanufacturing the same, the partial SOI substrate is provided with aburied semiconductor element. In this case, the buried semiconductorelement is provided securing a sufficient depth so that it can properlyfunction. In addition, the partial SOI substrate is provided with thesemiconductor element so as to prevent a substrate floating effect. Morespecifically, the semiconductor substrate 11 is provided with asemiconductor element.

As illustrated in FIG. 3, a trench 12 is formed in the non-SOI region(bulk region) 9 of the partial SOI substrate 11. In the firstembodiment, the trench 12 is formed over the range from the active layersurface of the single crystal silicon layer 8 to the deep part equal tothe lowest portion of the polycrystalline silicon layer 6 in the SOIregion 10. Using a standard method of manufacturing capacitor elements,an embedded plate electrode 13, capacitor insulating film 14 and storageelectrode 15 are formed in the trench 12. By doing so, an embeddedsemiconductor element, that is, a memory trench cell 16 as a secondsemiconductor element, is made in the bulk region 9.

Two isolation regions 17 are formed in the bulk region 9. In this case,one isolation region 17 is formed contacting with the SiO₂ film 4 at theboundary between the bulk region 9 and the SOI region 10. Well andchannel (not shown) are formed in the bulk region 9 and the SOI region10. A gate 18 and a gate insulator 19 are formed on the active layersurface of the single crystal silicon layer 8. The gate insulator iscomposed of bottom, upper and side wall portions 19 a to 19 c. Ions areimplanted in the active surface layer of the single crystal siliconlayer 8, and thereafter, a thermal diffusion process is carried out sothat source and drain 20 (21) can be formed. By doing so, a transistor22 as a first semiconductor element is made in each of the bulk region 9and the SOI region 10.

One of the source and drain 20 (21) formed in the bulk region 9 isformed so that it can be electrically connected with the upper end ofthe memory trench cell 16. The transistor 22 made in the SOI region 10has specification to substrate floating effect set lighter than thetransistor 22 made in the bulk region 9.

The process of manufacturing the semiconductor device of the firstembodiment ends. The process described above is carried out, andthereby, a desired semiconductor device 23 can be obtained. Namely, inthe semiconductor device 23, the memory trench cell 16 is formed havingsufficient depth in the bulk region 9 without crossing the interfacebetween the silicon layers 8 and 6. Therefore, the memory trench cell 16can secure sufficient capacitance, and properly function. In addition,there is no possibility that deterioration of performance by substratefloating effect occurs in the transistor 22 made in the bulk region 9;therefore, the transistor 22 can properly function. Incidentally, thememory trench cell 16 and transistor 22 formed in the bulk region 9 maybe used as the element of a logic circuit (not shown). Likewise, thetransistor 22 formed in the SOI region 10 may be used as the element ofa DRAM (not shown).

As described above, according to the first embodiment, the SOI region 10of the partial SOI substrate 11 has gettering ability to the non-SOIregion 9 adjacent thereto. In addition, the partial SOI substrate 11 canuse the entirety of the non-SOI region 9 as a good element formableregion.

In the method of manufacturing the semiconductor substrate according tothe embodiment, a two-stage epitaxial growth process is employed whenforming the single crystal silicon layer 8 (second single crystalsilicon layer 5). The two-stage epitaxial growth process includes aselective epitaxial growth process and entire surface epitaxial growthprocess. By doing so, the polycrystalline silicon layer 6 in the SOIregion 10 and the single crystal silicon layer 5 in the non-SOI region 9adjacent to there are concurrently formed at individual properpositions. Therefore, according to the method of manufacturing thesemiconductor substrate, it is possible to readily manufacture thepartial SOI substrate including the foregoing good partial SOI structureusing epitaxial growth process.

In the semiconductor device 23 of the embodiment, the transistor 22formed in the non-SOI region 9 of the partial SOI substrate 11 preventsthe occurrence of the substrate floating effect. In addition, the memorytrench cell 16 formed in the non-SOI region 9 is formed in a state ofsecuring a depth capable of enabling the capacitor element to functionproperly. Namely, in the semiconductor device 23, the memory trench cell16 and the transistor 22 are provided on the partial SOI substrate 11having a good partial SOI structure in a state to enable properfunctioning. Therefore, the semiconductor device 23 has high quality andreliability.

According to the method of manufacturing the semiconductor device of theembodiment, a semiconductor device 23 having high quality andreliability can be readily manufactured at high yield.

SECOND EMBODIMENT

The second embodiment of the present invention will be described withreference to FIG. 4A to FIG. 4E, FIG. 5A to FIG. 5D, and FIG. 6. FIG. 4Ato FIG. 4E and FIG. 5A to FIG. 5D are process sectional views showing amethod of manufacturing a semiconductor substrate according to thesecond embodiment. FIG. 6 is a cross-sectional view showing asemiconductor device according to the second embodiment. The samereference numerals are used to designate the portions identical to thefirst embodiment, and the details are omitted.

The semiconductor substrate according to the second embodiment and themethod of manufacturing 'the same will be described with reference toFIG. 4A to FIG. 4E and FIG. 5A to FIG. 5D. In the semiconductorsubstrate of the embodiment and the method of manufacturing the same, apartial SOI substrate having partial SOI structure is manufactured usinga so-called bonding process and solid phase epitaxial growth. In thepartial SOI structure, the non-single crystal silicon layer in the SOIregion does not intrude into the non-SOI region adjacent to the SOIregion.

As illustrated in FIG. 4A, the first silicon substrate 1 is providedwith the following multi-layer according to the same method as the firstembodiment. The multi-layer comprises the porous silicon layer 2, firstsingle crystal silicon layer 3 and the SiO₂ film 4 having the thicknessof about 0.2 μm.

As depicted in FIG. 4B, according to the same method as the firstembodiment, the SiO₂ film 4 equivalent to the region used as the non-SOIregion described later is removed. In this case, the SiO₂ film 4is-removed so that it remains in only region used as the SOI regiondescribed later.

As seen from FIG. 4C, an amorphous silicon layer 31 is formed over theexposed surface of the first single crystal silicon layer 3 and thesurface of the SiO₂ film 4. More specifically, the first siliconsubstrate 1 is heated until the substrate temperature becomes about 500°C. Thereafter, SiH₄ gas is supplied to the exposed surface of the firstsingle crystal silicon layer 3 and the surface of the SiO₂ film 4. Bydoing so, the amorphous silicon layer 31 is formed over the exposedsurface of the first single crystal silicon layer 3 and the surface ofthe SiO₂ film 4 until the film thickness becomes about 0.4 μm.

As shown in FIG. 4D, the amorphous silicon layer 31 above the firstsingle crystal silicon layer 3, which is not covered with the SiO₂ film4, is single-crystallized. The following is a detailed description.

The substrate temperature of the first silicon substrate formed with theamorphous silicon layer 31 is increased from about 500° C. to about 900°C. so that the amorphous silicon layer 31 can be heated. The amorphoussilicon layer 31 above the first single crystal silicon layer 3 exceptthe SiO₂ film 4 solid-phase epitaxially grows using the first singlecrystal layer 3 as the seed layer. Thus, the amorphous silicon layer 31is modified into a second single crystal silicon layer 32. The secondsingle crystal silicon layer 32 solid-phase epitaxially grows whilebeing integrated with the first single crystal silicon layer 3. In thiscase, the amorphous silicon layer 31 above the SiO₂ film 4 solid-phaseepitaxially grows using the SiO₂ film 4 as the front-end layer. Thus,the amorphous silicon layer 31 is modified into a polycrystallinesilicon layer 33.

The second single crystal silicon layer 32 grows along the thicknessdirection of the amorphous silicon layer 31. Thus, the amorphous siliconlayer 31 above the first single crystal silicon layer 3 except the SiO₂film 4 is all modified into the second single crystal silicon layer 32.After the second single crystal silicon layer 32 reaches the surface ofthe amorphous silicon layer 31, heating is further continued. By doingso, the amorphous silicon layer 31 on the SiO₂ film 4 starts to besingle-crystallized. Thus, the second single crystal silicon layer 32grows to ride on the surface of the edge portion of the SiO₂ film 4, asillustrated in FIG. 4E. In the embodiment, heating to the amorphoussilicon layer 31 is continued until the interface between the siliconlayers 32 and 33 reaches above the SiO₂ film 4.

As illustrated in FIG. 5A, the surfaces of the second single crystalsilicon layer 32 and the polycrystalline silicon layer 33 are subjectedto CMP process so that their surfaces can be planarized. By doing so,the surfaces of the second single crystal silicon layer 32 and thepolycrystalline silicon layer 33 are adjusted to approximately equalheight.

As shown in FIG. 5B, the second silicon substrate (third single crystalsilicon layer) 7 is bonded to the surfaces of the silicon layers 32 and33 according to the same method as the first embodiment. The bondedthird single crystal silicon layer 7 is integrated with the secondsingle crystal silicon layer 32. As seen from FIG. 5C, the first tothird single crystal silicon layers 3, 32 and 7 are integrated to formone single crystal silicon layer 34.

As shown in FIG. 5C and FIG. 5D, the active silicon layer is made thinaccording to the same method as the first embodiment, and thereafter,the surface is planarized. This ends the process of manufacturing thesemiconductor substrate of the second embodiment.

The process described above is carried out, and thereby, a semiconductorsubstrate (partial SOI substrate) 37 having the desired partial SOIstructure can be obtained. The partial SOI substrate 37 has the singlecrystal silicon layer 34 comprising first to third single crystalsilicon layers 3, 32 and 7, SiO₂ film (insulator) 4 and the partial SOIstructure having two regions, as seen from FIG. 5D. The partial SOIstructure includes a SOI region 36 comprising the polycrystallinesilicon layer (non-single crystal silicon layer) 33 and a non-SOI region(bulk region) 35 comprising only single crystal silicon layer 34. TheSOI region 36 and the non-SOI region 35 are adjacent to each other. Inthe partial SOI substrate 37, the polycrystalline silicon layer 33 isformed only on the main surface of the SiO₂ film 4 so that the interfacebetween the silicon layers 33 and 32 can be positioned on the mainsurface thereof. Namely, in the partial SOI substrate 37, thepolycrystalline silicon layer 33 capable of performing gettering abilityto the single crystal silicon layer 34 is left only in the SOI region36. Thus, the polycrystalline silicon layer 33 does not remain in thenon-SOI region 35 adjacent to the SOI region 36. Therefore, the wholenon-SOI region 35 can be used as a good element formable region.

A semiconductor device of the second embodiment and the method ofmanufacturing the same will be briefly described with reference to FIG.6. In the semiconductor device of the embodiment and the method ofmanufacturing the same, the semiconductor substrate 37 is provided withsemiconductor elements so the semiconductor elements can properlyfunction.

A semiconductor device 38 and manufacturing method of the secondembodiment is different from the semiconductor device 23 andmanufacturing method of the first embodiment, in the following point.That is, the partial SOI substrate 37 is used in place of the partialSOI substrate 11. In the semiconductor device 38, the memory trench cell16 is formed without crossing the interface between the silicon layer 34and 33. Further, the memory trench cell 16 is formed over the range fromthe active surface of the silicon layer 34 to the position sufficientlydeeper than the lowest portion of the silicon layer 33. By doing so, thememory trench cell 16 can secure a highly sufficient capacitance, andcan properly function. Of course, the transistor 22 formed in thenon-SOI region 35 prevents the substrate floating effect.

According to the second embodiment, the same effect as the firstembodiment can be obtained. In addition, the solid-phase epitaxialgrowth process is employed. By doing so, single crystal andpolycrystalline silicon layers 32 and 33 may be independently formed atproper positions using only one gas source. Therefore, according to themethod of manufacturing the semiconductor substrate, it is possible toreadily manufacture the partial SOI substrate 37 including the foregoinggood partial SOI structure. In this case, the partial SOI structure hasgettering ability sufficient to the non SOI region 35 adjacent to theSOI region 36 without making narrow the non-SOI region 35 by the SOIregion 36. In addition, the semiconductor device includes the partialSOI structure 37 having good partial SOI structure, and is provided withthe memory trench cell 16 and the transistor 22 capable of properlyfunctioning. As a result, it is possible to readily manufacture thesemiconductor device having high quality and reliability at high yield.

In the present invention, the semiconductor substrate, the method ofmanufacturing the same, the semiconductor device, and the method ofmanufacturing the same are not limited to the first and secondembodiments. Various settings of the structure or parts of the processmay be made, or various settings may be properly combined within thescope not departing from the spirit of the present invention.

For example, in the first embodiment, the width W and height of thesecond crystal silicon layer 5 riding on the SiO₂ film 4 may be set asfollows. The width W and height may be properly set in accordance withthe ratio of the growth speed of the silicon layer 5 grown in the nextprocess to that of the polycrystalline silicon layer 6. By doing so, theinclination angle θ of the interface between the silicon layers 5 and 6can be set to a proper magnitude. In other words, the intrusion(intrusion width) of the second crystal silicon layer 5 into the SOIregion 10 can be set to a proper magnitude. Likewise, in the secondembodiment, the width W and height of the second crystal silicon layer32 ridden on the SiO₂ film 4 may be set.

In the first embodiment, before the second single crystal silicon layer5 and the polycrystalline silicon layer 6 are concurrently formed, thesecond single crystal silicon layer 5 is formed. In this case, thesilicon layer 5 is formed to cover the exposed surface of the firstsingle crystal silicon layer 3 except the SiO₂ film 4 and the edgeportion of the SiO₂ film 4 adjacent to the exposed surface. However, thepresent invention is not limited to the deposition process describedabove. For example, the second single crystal silicon layer 5 is formedto cover the exposed surface of the first single crystal silicon layer 3and the entire surface of the SiO₂ film 4. The silicon layer 5 on theedge portion of the SiO₂ film 4 adjacent to the surface of the siliconlayer 3 is removed by predetermined lithography and etching processes.In addition, the second single crystal silicon layer 5 on the SiO₂ film4 is removed. Thereafter, the polycrystalline silicon layer 6 isselectively formed on the SiO₂ film 4 in which the second single crystalsilicon layer 5 has already been removed. According to the depositionprocess described above, the partial SOI substrate 11 having the desiredpartial SOI structure can be obtained like the first embodiment.

In the first and second embodiments, the active silicon layer is madethin using ELTRAN process readily controlling the thickness of thesilicon layer. The present invention is not limited to the ELTRANprocess. For example, the following process (UNIBOND process) may beemployed. According to the UNIBOND process, hydrogen ions are implantedto the active silicon layer, and thereafter, the silicon layer is madethin by heat treatment. In addition, the process may be employed suchthat the silicon layer is made thin by polishing such as CMP.

In the second embodiment, the surfaces of the second single crystalsilicon layer 32 and the polycrystalline silicon layer 33 are planarizedso that the height can be adjusted. CMP readily controlling the filmthickness is employed as the process described above. However, thepresent invention is not limited to the CMP process. For example, thesame effect can be obtained by wet etching. In addition, thermaloxidation and wet etching may be combined.

In the second embodiment, at least amorphous silicon layer 31 above thesingle crystal silicon layer 3 except the SiO₂ film 4 issingle-crystallized. However, the present invention is not limited tothe deposition process described above. For instance, the entireamorphous silicon layer 31 formed covering the exposed surface of thesilicon layer 3 and the entire surface of the SiO₂ film 4 is modifiedinto the second single crystal silicon layer 32 by heating. The secondsingle crystal silicon layer 32 on the edge portion of the SiO₂ film 4adjacent to the exposed surface of the silicon layer 3 is removed bypredetermined lithography and etching processes. In addition, the secondsingle crystal silicon layer 32 on the SiO₂ film 4 is removed.Thereafter, the polycrystalline silicon layer 33 is selectively formedon the SiO₂ film 4 in which the second single crystal silicon layer 32has already been removed. According to the deposition process describedabove, the partial SOI substrate 37 having the desired partial SOIstructure can be obtained, as in the second embodiment.

In the first and second embodiments, each of non-SOI regions (bulkregion) 9 and 35 of the partial SOI substrates 11 and 37 is formed withthe memory trench cell 16 and the transistor 22. On the other hand, eachof SOI regions 10 and 36 is formed with only transistor 22. The presentinvention is not limited to the structure described above. For example,the position and number of the memory trench cell 16 and transistor 22may be properly set in accordance with the desired configuration(structure) of the semiconductor devices 23 and 38. The partial SOIsubstrates 11 and 37 are provided with memory trench cell 16 andtransistor 22 as the semiconductor element. However, the semi-conductorelement is not limited to components described above. The partial SOIsubstrates 11 and 37 may be provided with various semiconductor elementsin accordance with the configuration of the-desired semiconductor deices23 and 38.

Of course, the partial SOI substrates 11 and 37 having good partial SOIstructure are applicable to semiconductor devices embeddinghigh-performance logic circuits and DRAMs onto one chip. In particular,the partial SOI substrates 11 and 37 are applicable to SOI-MOSFETforming MOSFET on the SOI substrate.

Additional advantages and modifications will readily occur to thoseskilled in the art. Therefore, the invention in its broader aspects isnot limited to the specific details and representative embodiments shownand described herein. Accordingly, various modifications may be madewithout departing from the spirit or scope of the general inventiveconcept as defined by the appended claims and their equivalents.

1. A method of manufacturing a semiconductor substrate comprising:forming an insulator to partially cover one main surface of a firstsingle crystal silicon layer; epitaxially growing a second singlecrystal silicon layer on an exposed surface of the first single crystalsilicon layer which is not covered with the insulator, to cover an edgeportion of the insulator adjacent to the exposed surface; and forming anon-single crystal silicon layer on an exposed surface of the insulatorwith an end of an interface between the insulator and the non-singlecrystal silicon layer kept away from an end of the insulator by apredetermined distance, while further epitaxially growing the secondsingle crystal silicon layer.
 2. A method according to claim 1, whereinmaterial gas containing Cl is used, and thereby, the second singlecrystal silicon layer is selectively and epitaxially grown mainly on theexposed surface of the first single crystal silicon layer using thefirst single crystal silicon layer as a seed layer.
 3. A methodaccording to claim 1, wherein a polycrystalline silicon layer is formedas the non-single crystal silicon layer.
 4. A method according to claim1, further comprising: forming a third single crystal silicon layer tocover the surfaces of the second single crystal silicon layer and thenon-single crystal silicon layer.
 5. A method according to claim 1,further comprising: making thin the first single crystal silicon layer.6. A method according to claim 1, wherein material gas containing no Clis used, and thereby, the second single crystal silicon layer isepitaxially grown on the entire surface of the first single crystalsilicon layer and the insulator concurrently with the non-single crystalsilicon layer.
 7. A method of manufacturing a semiconductor substratecomprising: forming an insulator to partially cover one main surface ofa first single crystal silicon layer; forming an amorphous silicon layerto cover a surface of the insulator and an exposed surface of the firstsingle crystal silicon layer which is not covered with the insulator;and heating the amorphous silicon layer until the amorphous siliconlayer on the exposed surface of the first single crystal silicon layerwhich is not covered with the insulator, is modified into a secondsingle crystal silicon layer by selectively and solid-phase epitaxiallygrowing, using the first single crystal silicon layer as a seed layer.8. A method according to claim 7, wherein the amorphous silicon layerwhich is not modified into the second single crystal silicon layer bythe heating, is modified into a polycrystalline silicon layer by theheating.
 9. A method according to claim 7, further comprising: forming athird single crystal silicon layer to cover a surface of the secondsingle crystal silicon layer modified from the amorphous silicon layerby said heating, and to cover a surface of the amorphous silicon layerwhich is not modified into the second single crystal silicon layer. 10.A method according to claim 7, further comprising: making thin the firstsingle crystal silicon layer.
 11. A method according to claim 7, whereinthe third single crystal silicon layer is formed integrally with thesecond single crystal silicon layer by bonding process.
 12. A method ofmanufacturing a semiconductor device comprising: manufacturing asemiconductor substrate; the semiconductor substrate including; a firstsingle crystal silicon layer; an insulator formed to partially cover onemain surface of the first single crystal silicon layer; a second singlecrystal silicon layer formed to cover a region of the first singlecrystal silicon layer which is not covered with the insulator, and tocover an edge portion of the insulator adjacent to the region; and anon-single crystal silicon layer formed on the insulator, the interfacebetween the non-single crystal silicon layer and the second singlecrystal silicon layer being positioned on the insulator; forming a firstsemiconductor element on an surface of the first single crystal siliconlayer or in a range from the surface to a predetermined inside positionof the first single crystal silicon layer, at a position off theinsulator of the semiconductor substrate; and forming a secondsemiconductor element in a range from a surface of the first singlecrystal silicon layer to at least inside of the second single crystalsilicon layer, at a position off the insulator of the semiconductorsubstrate.
 13. A method of manufacturing a semiconductor devicecomprising: manufacturing a semiconductor substrate; the semiconductorsubstrate including; forming an insulator to partially cover one mainsurface of a first single crystal silicon layer; epitaxially growing asecond single crystal silicon layer on an exposed surface of the firstsingle crystal silicon layer which is not covered with the insulator, tocover an edge portion of the insulator adjacent to the exposed surface;and forming a non-single crystal silicon layer on an exposed surface ofthe insulator while further epitaxially growing the second singlecrystal silicon layer; forming a first semiconductor element on ansurface of the first single crystal silicon layer or in a range from thesurface to a predetermined inside position of the first single crystalsilicon layer, at a position off the insulator of the semiconductorsubstrate; and forming a second semiconductor element in a range from asurface of the first single crystal silicon layer to at least inside ofthe second single crystal silicon layer, at a position off the insulatorof the semiconductor substrate.
 14. A method of manufacturing asemiconductor device comprising: manufacturing a semiconductorsubstrate; the semiconductor substrate including; forming an insulatorto partially cover one main surface of a first single crystal siliconlayer; forming an amorphous silicon layer to cover a surface of theinsulator and an exposed surface of the first single crystal siliconlayer which is not covered with the insulator; and heating the amorphoussilicon layer until the amorphous silicon layer on the exposed surfaceof the first single crystal silicon layer which is not covered with theinsulator, is modified into a second single crystal silicon layer byselectively and solid-phase epitaxially growing, using the first singlecrystal silicon layer as a seed layer; forming a first semiconductorelement on an surface of the first single crystal silicon layer or in arange from the surface to a predetermined inside position of the firstsingle crystal silicon layer, at a position off the insulator of thesemiconductor substrate; and forming a second semiconductor element in arange from a surface of the first single crystal silicon layer to atleast inside of the second single crystal silicon layer, at a positionoff the insulator of the semiconductor substrate.